NTFS: Difference between revisions
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| introduction_date = July 1993 |
| introduction_date = July 1993 |
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| partition_id = 0x07 ([[Master boot record|MBR]]) <br /> <tt>[[Basic Data Partition|EBD0A0A2-B9E5-4433-87C0-68B6B72699C7]]</tt> ([[GUID Partition Table|GPT]]) |
| partition_id = 0x07 ([[Master boot record|MBR]]) <br /> <tt>[[Basic Data Partition|EBD0A0A2-B9E5-4433-87C0-68B6B72699C7]]</tt> ([[GUID Partition Table|GPT]]) |
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| directory_struct = [[B |
| directory_struct = [[B-tree]] |
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| file_struct = Bitmap/Extents |
| file_struct = Bitmap/Extents |
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| bad_blocks_struct = Bitmap/Extents |
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NTFS allows any sequence of 16-bit values for name encoding (file names, stream names, index names, etc.). This means UTF-16 codepoints are supported, but the file system does not check whether a sequence is valid [[UTF-16]] (it allows any sequence of short values, not restricted to those in the Unicode standard). |
NTFS allows any sequence of 16-bit values for name encoding (file names, stream names, index names, etc.). This means UTF-16 codepoints are supported, but the file system does not check whether a sequence is valid [[UTF-16]] (it allows any sequence of short values, not restricted to those in the Unicode standard). |
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Internally, NTFS uses [[B |
Internally, NTFS uses [[B-tree]]s to index file system data. Although complex to implement, this allows faster file look up times in most cases. A file system journal is used to guarantee the integrity of the file system—but not individual files' content. Systems using NTFS are known to have improved reliability compared to FAT file systems.<ref>"[http://www.microsoft.com/technet/archive/ntwrkstn/reskit/file_sys.mspx?mfr=true Microsoft TechNet Resource Kit]"</ref> |
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The Master File Table (MFT) contains [[metadata]] about every file, directory, and metafile on an NTFS volume. It includes filenames, locations, size, and permissions. Its structure supports algorithms which minimize [[file system fragmentation|disk fragmentation]]. A directory entry consists of a filename and a "file ID" which is the record number representing the file in the Master File Table. The file ID also contains a reuse count to detect stale references. While this strongly resembles the W_FID of [[Files-11]], other NTFS structures radically differ. |
The Master File Table (MFT) contains [[metadata]] about every file, directory, and metafile on an NTFS volume. It includes filenames, locations, size, and permissions. Its structure supports algorithms which minimize [[file system fragmentation|disk fragmentation]]. A directory entry consists of a filename and a "file ID" which is the record number representing the file in the Master File Table. The file ID also contains a reuse count to detect stale references. While this strongly resembles the W_FID of [[Files-11]], other NTFS structures radically differ. |
Revision as of 14:53, 16 April 2008
Developer(s) | Microsoft |
---|---|
Full name | NTFS |
Introduced | July 1993 with Windows NT 3.1 |
Partition IDs | 0x07 (MBR) EBD0A0A2-B9E5-4433-87C0-68B6B72699C7 (GPT) |
Structures | |
Directory contents | B-tree |
File allocation | Bitmap/Extents |
Bad blocks | Bitmap/Extents |
Limits | |
Max volume size | 264 − 1 clusters [1] |
Max file size | 264 bytes (16 EiB) minus 1 KiB [1] |
Max no. of files | 4,294,967,295 (232-1)[1] |
Max filename length | 255 UTF-16 code units[2] |
Allowed filename characters | In Posix namespace, any UTF-16 code unit (case sensitive) except U+0000 (NUL) and / (slash). In Win32 namespace, any UTF-16 code unit (case insensitive) except U+0000 (NUL) / (slash) \ (backslash) : (colon) * (asterisk) ? (Question mark) " (quote) < (less than) > (greater than) and | (pipe) [2] |
Features | |
Dates recorded | Creation, modification, POSIX change, access |
Date range | 1 January 1601 – 28 May 60056 (File times are 64-bit numbers counting 100-nanosecond intervals (ten million per second) since 1601, which is 58,000+ years) |
Date resolution | 100ns |
Forks | Yes (see Alternate data streams below) |
Attributes | Read-only, hidden, system, archive, not content indexed, off-line, temporary |
File system permissions | ACLs |
Transparent compression | Per-file, LZ77 (Windows NT 3.51 onward) |
Transparent encryption | Per-file, DESX (Windows 2000 onward), Triple DES (Windows XP onward), AES (Windows XP Service Pack 1, Windows Server 2003 onward) |
Other | |
Supported operating systems | Windows NT family (Windows NT 3.1 to Windows NT 4.0, Windows 2000, Windows XP, Windows Server 2003, Windows Vista, Windows Server 2008) |
NTFS is the standard file system of Windows NT, including its later versions Windows 2000, Windows XP, Windows Server 2003, Windows Server 2008, and Windows Vista.[3]
NTFS supersedes the FAT file system as the preferred file system for Microsoft’s “Windows”-branded operating systems. NTFS has several improvements over FAT and HPFS (High Performance File System) such as improved support for metadata and the use of advanced data structures to improve performance, reliability, and disk space utilization, plus additional extensions such as security access control lists (ACL) and file system journaling. The exact file system specification is a trade secret, although (since NTFS v3.00) it can be licensed commercially from Microsoft through their Intellectual Property Licensing program.
History
In the early 1990s Microsoft and IBM formed a joint project to create the next generation graphical operating system. The result of the project was OS/2, but eventually Microsoft and IBM disagreed on many important issues and separated. OS/2 remained an IBM project. Microsoft started to work on Windows NT. The OS/2 filesystem HPFS contained several important features. When Microsoft created their new operating system, they borrowed many of these concepts for NTFS.[4] Perhaps as a result of this, HPFS and NTFS share the same disk partition identification type code (07). This is unusual since the other major filesystems have their own code; FAT has more than nine (one each for FAT12, FAT16, FAT32, etc.). To identify the type of filesystem in a partition type 07, additional checks are needed.
Versions
NTFS has five released versions: (the alternate names are due to the fact that the OS version is sometimes set in line with the NTFS version)
- v1.0 with NT 3.1,[citation needed] released mid-1993
- v1.1 with NT 3.5,[citation needed] released autumn 1994
- v1.2 written by NT 3.51 (mid-1995) and NT 4 (mid-1996) (occasionally referred to as "NTFS 4.0", because OS version is 4.0)
- v3.0 from Windows 2000 (occasionally "NTFS V5.0")
- v3.1 from Windows XP (autumn 2001; occasionally "NTFS V5.1"), Windows Server 2003 (spring 2003; occasionally "NTFS V5.2"),Windows Vista (mid-2005) (occasionally "NTFS V6.0") and Windows Server 2008
V1.0 and V1.2 are incompatible: that is, volumes written by NT 3.5x cannot be read by NT 3.1 until an update on the NT 3.5x CD is applied to NT 3.1, which also adds FAT long file name support.[5] V1.2 supported compressed files, named streams, ACL-based security, etc.[6] V3.0 added disk quotas, encryption, sparse files, reparse points, update sequence number (USN) journaling, the $Extend folder and its files, and reorganized security descriptors so that multiple files which use the same security setting can share the same descriptor.[7] V3.1 expanded the MFT entries with redundant MFT record number (useful for recovering damaged MFT files).
Windows Vista introduced Transactional NTFS, NTFS symbolic links, and self-healing functionality[8] though those owe more to additional functionality of the operating system than the filesystem itself. Yet the NTFS version number has not been raised.
Features
NTFS v3.0, the third version of NTFS to be introduced, includes several new features over its predecessors: disk usage quotas, sparse file support, reparse points, distributed link tracking and file-level encryption, also known as the Encrypting File System (EFS).
- Alternate data streams (ADS)
- Alternate data streams allows files to be associated with more than one data stream. For example, a file such as text.txt can have an ADS with the name of text.txt:secret.txt (of form filename:ads) that can only be accessed by knowing the ADS name or by specialized directory browsing programs. Alternate streams are not detectable in the original file's size but are lost when the original file (i.e. text.txt) is deleted with a RemoveFile or RemoveFileTransacted call (or a call that uses those calls), or when the file is copied or moved to a partition that doesn't support ADS (e.g. a FAT partition, a floppy disk, or a network share). While ADS is a useful feature, it can also easily eat up hard disk space if unknown either through being forgotten or not being detected.
- Quotas
- Disk quotas were introduced in NTFS v3. They allow the administrator of a computer that runs a version of Windows that supports NTFS to set a threshold of disk space that users may utilize. It also allows administrators to keep track of how much disk space each user is using. An administrator may specify a certain level of disk space that a user may use before they receive a warning, and then deny access to the user once they hit their upper limit of space. Disk quotas do not take into account NTFS's transparent file-compression, should this be enabled. Applications that query the amount of free space will also see the amount of free space left to the user who has a quota applied to them.
- Sparse files
- Sparse files are files which contain sparse data sets, data mostly filled with zeroes. Many scientific applications can generate very large sparse data sets. Because of this, Microsoft has implemented support for sparse files by allowing an application to specify regions of empty (zero) data. An application that reads a sparse file reads it in the normal manner with the file system calculating what data should be returned based upon the file offset. As with compressed files, the actual size of sparse files are not taken into account when determining quota limits.[9][10]
- Reparse points
- This feature was introduced in NTFS v3. These are used by associating a reparse tag in the user space attribute of a file or directory. When the object manager (see Windows NT line executive) parses a file system name lookup and encounters a reparse attribute, it knows to reparse the name lookup, passing the user controlled reparse data to every file system filter driver that is loaded into Windows 2000. Each filter driver examines the reparse data to see if it is associated with that reparse point, and if that filter driver determines a match then it intercepts the file system call and executes its special functionality. Reparse points are used to implement Volume Mount Points, Directory Junctions, Hierarchical Storage Management, Native Structured Storage and Single Instance Storage:
- Volume mount points
- Similar to Unix mount points, where the root of another file system is attached to a directory. In NTFS, this allows additional file systems to be mounted without requiring a separate drive letter (like C: or D:) for each.
- Directory Junctions
- Similar to Volume Mount Points, however directory junctions reference other directories in the file system instead of other volumes. For instance, the directory
C:\exampledir
with a directory junction attribute that contains a link toD:\linkeddir
will automatically refer to the directoryD:\linkeddir
when it is accessed by a user-mode application. [11] This function is conceptually similar to symbolic links to directories in Unix except that the target in NTFS must always be another directory. (Typical Unix file systems allow the target of a symbolic link to be any type of file.) - Hard links
- Originally included to support the POSIX subsystem in Windows NT[12], hard links are similar to directory junctions, but used for files instead of directories. Hard links can only be applied to files on the same volume since an additional filename record is added to the file's MFT record. Short (8.3) filenames are also implemented as additional filename records that don't have separate directory entries.
- Hierarchical Storage Management (HSM)
- Hierarchical Storage Management is a means of transferring files that are not used for some period of time to less expensive storage media. When the file is next accessed the reparse point on that file determines that it is needed and retrieves it from storage.
- Native Structured Storage (NSS)
- NSS was an ActiveX document storage technology that has since been discontinued by Microsoft. It allowed ActiveX Documents to be stored in the same multi-stream format that ActiveX uses internally. An NSS file system filter was loaded and used to process the multiple streams transparently to the application, and when the file was transferred to a non-NTFS formatted disk volume it would also transfer the multiple streams into a single stream.[13]
- Volume Shadow Copy
- The Volume Shadow Copy (VSC) service keeps historical versions of files and folders on NTFS volumes by copying old, newly-overwritten data to shadow copy (copy-on-write). The old file data is overlaid on the new when the user requests a revert to an earlier version. This also allows data backup programs to archive files currently in use by the file system. On heavily loaded systems, Microsoft recommends setting up a shadow copy volume on separate disk to reduce the I/O load on the main volume.
- File compression
- NTFS can compress files using a variant of the LZ77 algorithm (also used in the popular ZIP file format).[14] Although read-write access to compressed files is transparent, Microsoft recommends avoiding compression on server systems and/or network shares holding roaming profiles because it puts a considerable load on the processor.[15]
- Single-user systems with limited hard disk space will probably use NTFS compression successfully.[citation needed] The slowest link in a notebook is not the CPU but the speed of the hard drive, so NTFS compression allows the limited, slow storage space to be better used, in terms of both space and (often) speed.[16] NTFS compression can also serve as a replacement for sparse files when a program (e.g. a download manager) is not able to create files without content as sparse files.
- Single Instance Storage (SIS)
- When there are several directories that have different, but similar, files, some of these files may have identical content. Single instance storage allows identical files to be merged to one file and create references to that merged file. SIS consists of a file system filter that manages copies, modification and merges to files; and a user space service (or groveler) that searches for files that are identical and need merging. SIS was mainly designed for remote installation servers as these may have multiple installation images that contain many identical files; SIS allows these to be consolidated but, unlike for example hard links, each file remains distinct; changes to one copy of a file will leave others unaltered. This is similar to copy-on-write, which is a technique by which memory copying is not really done until one copy is modified.[17]
- Encrypting File System (EFS)
- EFS provides strong and user-transparent encryption of any file or folder on an NTFS volume. EFS works in conjunction with the EFS service, Microsoft's CryptoAPI and the EFS File System Run-Time Library (FSRTL).
- EFS works by encrypting a file with a bulk symmetric key (also known as the File Encryption Key, or FEK), which is used because it takes a relatively smaller amount of time to encrypt and decrypt large amounts of data than if an asymmetric key cipher is used. The symmetric key that is used to encrypt the file is then encrypted with a public key that is associated with the user who encrypted the file, and this encrypted data is stored in an alternate data stream of the encrypted file. To decrypt the file, the file system uses the private key of the user to decrypt the symmetric key that is stored in the file header. It then uses the symmetric key to decrypt the file. Because this is done at the file system level, it is transparent to the user.[18] Also, in case of a user losing access to their key, support for recovery agents that can unencrypt files has been built in to the EFS system.
- Symbolic links
- Symbolic links were originally used to support the POSIX subsystem in Windows NT.[citation needed] Symbolic links (or Soft links) are resolved on the client side. So when a symbolic link is shared, the target is subject to the access restrictions on the client, and not the server.
- Transactional NTFS
- As of Windows Vista, applications can use Transactional NTFS to group changes to files together into a transaction. The transaction will guarantee that all changes happen, or none of them do, and it will guarantee that applications outside the transaction will not see the changes until the precise instant they're committed.[19]
- Change Journal
- Record the changes of files.
Interoperability
Details on the implementation's internals are closed, which makes it difficult for third-party vendors to provide tools to handle NTFS.
Linux
Full and safe read/write of NTFS is provided by the NTFS-3G driver. It is included in most Linux distributions.
Other outdated and mostly read-only solutions exist as well:
- Linux kernel 2.2: NTFS partitions can be read by the kernel since version 2.2.0.
- Linux kernel 2.6: contains a driver written by Anton Altaparmakov (University of Cambridge) and Richard Russon. It supports file read, overwrite and resize, in some cases.
- NTFSMount: A userspace driver with limited file and directory read/write support is available using ntfsmount[20]
- NTFS for Linux: A commercial driver with full read/write support available from Paragon.
- Captive NTFS: A 'wrapping' driver which uses Windows's own driver, ntfs.sys.
Note that all three userspace drivers, namely NTFSMount, NTFS-3G and Captive NTFS, are built on the Filesystem in Userspace (FUSE), a Linux kernel module tasked with bridging userspace and kernel code to save and retrieve data.
Almost all drivers listed above (except Paragon NTFS for Linux) are open source (GPL). Due to the complexity of internal NTFS structures, both the built-in 2.6.14 kernel driver and the FUSE drivers disallow changes to the volume that are considered unsafe, to avoid corruption.
Windows
While the different NTFS versions have a great degree of both forward and backward compatibility, there are technical considerations for mounting newer NTFS volumes in older versions of Windows. This affects dual-booting, and external portable hard drives.
For example, "Previous Versions" (a.k.a. Volume Shadow Copy) are lost because the older OS doesn't understand how to keep the new features' data updated.[21]
Others
eComStation, KolibriOS, and Mac OS X versions 10.3 and later offer read-only NTFS support (there is a beta NTFS driver that allows write/delete for eComStation, but is generally considered unsafe). A free third-party tool for BeOS, which was based on NTFS-3G, allows full NTFS read and write.
A commercial read/write driver for DOS called "NTFS4DOS" also exists.[1]
A commercial solution for Mac OS X with read/write access is "Paragon NTFS for Mac OS X".[2]
Compatibility with FAT
Microsoft currently provides a tool (convert.exe) to convert HPFS (only on Windows NT 3), FAT16 and, on Windows 2000 and higher, FAT32 to NTFS, but not the other way around.[22] Various third-party tools are all capable of safely resizing NTFS partitions. Microsoft added the ability to shrink or expand a partition with Windows Vista.
For historical reasons, the versions of Windows that do not support NTFS all keep time internally as local zone time, and therefore so do all file systems other than NTFS that are supported by current versions of Windows. However, Windows NT and its descendants keep internal timestamps as UTC and make the appropriate conversions for display purposes. Therefore, NTFS timestamps are in UTC. This means that when files are copied or moved between NTFS and non-NTFS partitions, the OS needs to convert timestamps on the fly. But if some files are moved when daylight saving time (DST) is in effect, and other files are moved when standard time is in effect, there can be some ambiguities in the conversions. As a result, especially shortly after one of the days on which local zone time changes, users may observe that some files have timestamps that are incorrect by one hour. Due to the differences in implementation of DST between the northern and southern hemispheres, this can result in a potential timestamp error of up to 4 hours in any given 12 months.[23]
Internals
In NTFS, all file data—file name, creation date, access permissions, and contents—are stored as metadata. This abstract approach allowed easy addition of file system features during Windows NT's development — an interesting example is the addition of fields for indexing used by the Active Directory software.
NTFS allows any sequence of 16-bit values for name encoding (file names, stream names, index names, etc.). This means UTF-16 codepoints are supported, but the file system does not check whether a sequence is valid UTF-16 (it allows any sequence of short values, not restricted to those in the Unicode standard).
Internally, NTFS uses B-trees to index file system data. Although complex to implement, this allows faster file look up times in most cases. A file system journal is used to guarantee the integrity of the file system—but not individual files' content. Systems using NTFS are known to have improved reliability compared to FAT file systems.[24]
The Master File Table (MFT) contains metadata about every file, directory, and metafile on an NTFS volume. It includes filenames, locations, size, and permissions. Its structure supports algorithms which minimize disk fragmentation. A directory entry consists of a filename and a "file ID" which is the record number representing the file in the Master File Table. The file ID also contains a reuse count to detect stale references. While this strongly resembles the W_FID of Files-11, other NTFS structures radically differ.
Metafiles
NTFS contains several files which define and organize the file system. In all respects, most of these files are structured like any other user file ($Volume being the most peculiar), but are not of direct interest to file system clients. These metafiles define files, back up critical file system data, buffer file system changes, manage free space allocation, satisfy BIOS expectations, track bad allocation units, and store security and disk space usage information.
Segment Number | File Name | Purpose |
---|---|---|
0 | $MFT | Describes all files on the volume, including file names, timestamps, stream names and lists of cluster numbers where data streams reside, indexes, security identifiers, and file attributes like "read only", "compressed", "encrypted", etc. |
1 | $MFTMirr | Is a duplicate of the first vital entries of $MFT, usually 4 entries (4 KiB). |
2 | $LogFile | Contains transaction log of file system changes for metadata consistency. |
3 | $Volume | Contains information about the volume, namely the volume object identifier, volume label, file system version, and volume flags (mounted, chkdsk requested, requested $LogFile resize, mounted on NT 4, volume serial number updating, structure upgrade request). The volume serial number is in $Boot file. |
4 | $AttrDef | A table of NTFS attributes used with names, numbers and descriptions. |
5 | . | Root directory. |
6 | $Bitmap | A table of bit entries representing if particular cluster on the volume is used or free. |
7 | $Boot | Volume boot record. This file located at first cluster on the volume includes bootstrap code (used to find and launch NTLDR/ BOOTMGR and a BIOS parameter block including volume serial number and cluster numbers of $MFT and $MFTMirr. |
8 | $BadClus | A file which contains all the clusters marked as having bad sectors. This file simplifies cluster management by the chkdsk utility, both as a place to put newly discovered bad sectors, and for identifying unreferenced clusters. |
9 | $Secure | Access control list database which reduces overhead having many identical ACLs stored with each file, by uniquely storing these ACLs in this database only (contains two indices $SII: perhaps[citation needed] Security ID Index and $SDH: Security Descriptor Hash which index the stream named $SDS containing actual ACL table).[25] |
10 | $UpCase | A table of unicode uppercased characters for ensuring case insensitivity in Win32 and DOS namespaces. |
11 | $Extend | A filesystem directory containing various optional extensions, such as $Quota, $ObjId, $Reparse or $UsnJrnl. |
12 ... 23 | Reserved. | |
usually 24 | $Extend\$Quota | Contains information regarding disk quotas. |
usually 25 | $Extend\$ObjId | Contains information used for distributed link tracking. |
usually 26 | $Extend\$Reparse | Contains backreferences of all reparse points (such as symbolic links) on the volume |
27 ... | file.ext | Beginning of regular file entries. |
These metafiles are treated specially by NTFS and are difficult to directly view: special purpose-built tools are needed.
Resident vs. non-resident files
To optimize storage for the common case of small data files, NTFS prefers to place file data within the master file table—if it fits, instead of using MFT space to list clusters containing the data. The former is called "resident data" by computer forensics workers. The amount of data which fits is highly dependent on the file's characteristics, but 700 to 800 bytes is common in single-stream files with non-lengthy filenames and no ACLs. Encrypted-by-NTFS, sparse, or compressed files cannot be resident.
Since resident files do not directly occupy clusters ("allocation units"), it is possible for an NTFS volume to contain more files on a volume than there are clusters. For example, an 80 GB (74.5 GiB) partition NTFS formats with 19,543,064 clusters of 4 KiB. Subtracting system files (64 MiB log file, a 2,442,888-byte $Bitmap file, and about 25 clusters of fixed overhead) leaves 19,526,158 clusters free for files and indices. Since there are four MFT records per cluster, this volume theoretically could hold almost 4 × 19,526,158 = 78,104,632 resident files.
Limitations
The following are a few limitations of NTFS:
- Reserved File Names
- Though the file system supports paths up to about 32767 Unicode characters[26] with each path component (directory or filename) up to 255 characters[26] long, certain names are unusable, since NTFS stores its metadata in regular (albeit hidden and for the most part inaccessible) files; accordingly, user files cannot use these names. These files are all in the root directory of a volume (and are reserved only for that directory). The names are: $MFT, $MFTMirr, $LogFile, $Volume, $AttrDef, . (dot), $Bitmap, $Boot, $BadClus, $Secure, $Upcase, and $Extend;[1] . (dot) and $Extend are both directories; the others are files.
- Maximum Volume Size
- In theory, the maximum NTFS volume size is 264-1 clusters. However, the maximum NTFS volume size as implemented in Windows XP Professional is 232-1 clusters. For example, using 64 KiB clusters, the maximum NTFS volume size is 256 TiB minus 64 KiB. Using the default cluster size of 4 KiB, the maximum NTFS volume size is 16 TiB minus 4 KiB. Because partition tables on master boot record (MBR) disks only support partition sizes up to 2 TiB, dynamic or GPT volumes must be used to create bootable NTFS volumes over 2 TiB.
- Maximum File Size
- Theoretical: 16 EiB minus 1 KiB ( bytes). Implementation: 16 TiB minus 64 KiB ( bytes)
- Alternate Data Streams
- Windows system calls may—or may not—handle alternate data streams.[1] Depending on the operating system, utility and remote file system, a file transfer might silently strip data streams.[1] A safe way of copying or moving files is to use the BackupRead and BackupWrite system calls, which allow programs to enumerate streams, to verify whether each stream should be written to the destination volume and to knowingly skip offending streams.[1]
- Maximum path length
- An absolute path may be up to 32767 characters[26] long; a relative path is limited to 255 characters.
- Date range
- NTFS uses the same time reckoning as Windows NT: 64-bit timestamps with a range from January 11601 to May 28 60056 at a resolution of ten million ticks per second.
Developers
NTFS developers include:
- Tom Miller
- Gary Kimura
- Brian Andrew
- David Goebel
References
- ^ a b c d e f g Microsoft Corporation. "How NTFS Works". Retrieved 2008-01-27.
- ^ a b Richard Russon and Yuval Fledel. "NTFS Documentation". Retrieved 2007-07-01.
- ^ Custer, Helen (1994). Inside the Windows NT File System. Microsoft Press. ISBN 978-1-55615-660-1.
- ^ Kozierok, Charles M. (April 17, 2001). "Overview and History of NTFS". PCGuide.
- ^ "Recovering Windows NT After a Boot Failure on an NTFS Drive". Microsoft. November 1, 2006.
- ^ Inside Win2K NTFS, Part 1,page1 ohg2001
- ^ Inside Win2K NTFS, Part 1
- ^ Loveall, John (2006). "Storage improvements in Windows Vista and Windows Server 2008" (PowerPoint). Microsoft Corporation. pp. 14–20. Retrieved 2007-09-04.
- ^ "Sparse Files". MSDN Platform SDK: File Systems. Retrieved 2005-05-22.
- ^ "Sparse FIles and Disk Quotas". Win32 and COM Development: File Systems. Retrieved 2007-12-05.
- ^ Mark Russinovich, "Inside Win2K NTFS, Part 1"
- ^ MS Windows NT Workstation 4.0 Resource Guide, "POSIX Compatibility"
- ^ John Saville, "What is Native Structured Storage?"
- ^ "File Compression and Decompression". MSDN Platform SDK: File Systems. Retrieved 2005-08-18.
- ^ "Best practices for NTFS compression in Windows." Microsoft Knowledge Base. Retrieved on 2005-08-18.
- ^ Daily, Sean (January 1998). "Optimizing Disks". IDG books. Retrieved 2007-12-17.
- ^ "Single Instance Storage in Windows 2000" (PDF). Microsoft Research and Balder Technology Group.
- ^ How EFS Works, Microsoft Windows 2000 Resource Kit
- ^ "Transactional NTFS". MSDN. Retrieved 2007-02-02.
- ^ "ntfsmount wiki page on linux-ntfs.org"
- ^ cfsbloggers (July 14, 2006). "How restore points and other recovery features in Windows Vista are affected when dual-booting with Windows XP". The Filing Cabinet. Retrieved 2007-03-21.
- ^ "How to Convert FAT Disks to NTFS". Microsoft Corporation. 2001-10-25. Retrieved 2007-08-27.
{{cite web}}
: Check date values in:|date=
(help) - ^ "Beating the Daylight Savings Time bug and getting correct file modification times" The Code Project
- ^ "Microsoft TechNet Resource Kit"
- ^ Mark Russinovich (November 2000). "Inside Win2K NTFS, Part 1: New features improve efficiency, optimize disk utilization, and enable developers to add functionality". Windows 2000 Magazine. Microsoft. Retrieved 2008-01-14.
- ^ a b c More precisely, 32767 resp. 255 UTF-16 code words. Some rare/unusual Unicode characters require two such words.
- Bolosky, William J.; Corbin, Scott; Goebel, David; & Douceur, John R. (date). "Single Instance Storage in Windows 2000" (PDF). Microsoft Research & Balder Technology Group, Inc.
{{cite journal}}
: Check date values in:|date=
(help); Cite journal requires|journal=
(help)CS1 maint: multiple names: authors list (link) - Custer, Helen (1994). Inside the Windows NT File System. Microsoft Press. ISBN 978-1-55615-660-1.
- Nagar, Rajeev (1997). Windows NT File System Internals: A Developer's Guide. O'Reilly. ISBN 978-1-56592-249-5.
See also
- Comparison of file systems
- Files-11 — ODS-2 is structurally very similar to NTFS (compare
INDEXF.SYS
and$Mft
, andBITMAP.SYS
and$Bitmap
, for examples) - HPFS
External links
- NTFS-3G – an open source read/write NTFS driver for Linux, FreeBSD, Mac OS X, NetBSD, and Haiku.
- Linux-NTFS – an open source project to add NTFS support to the Linux kernel (write support is limited, but can be used for simple tasks), and write POSIX-compatible utilities for accessing and manipulating NTFS (ntfsprogs; includes ntfsls, ntfsresize, ntfsclone, etc). Linux NTFS FAQ and howto
- Captive NTFS – a shim which used the Windows NTFS driver to access NTFS file systems under Linux
- NTFS.com – documentation and resources for NTFS
- Microsoft NTFS Technical Reference